\subsection{Board Support Packages}
\label{sec:hdl_board}

The White Rabbit (WR) PTP core project provides board support packages (BSPs) for the following
boards:
\begin{itemize}
\item \href{http://www.ohwr.org/projects/spec}{SPEC}, a PCIe single FMC carrier board based on a
  Xilinx Spartan 6 FPGA.
\item \href{http://www.ohwr.org/projects/svec}{SVEC}, a VME dual FMC carrier board based on a Xilinx
  Spartan 6 FPGA.
\item \href{http://www.ohwr.org/projects/vfc-hd}{VFC-HD}, a VME single FMC carrier board based on an
  Altera Arria V FPGA.
\end{itemize}

By using these modules, users gain the benefit of instantiating all the necessary components of the
WR PTP core (including the core itself, the PHY, PLLs, etc.) in one go, without having to delve into
the implementation details, using a setup that has been tested and is known to work well on the
supported boards.

Each BSP is split in two modules: the common module, which is shared across all BSPs, and the
board-specific module. The common module instantiates the WRPC itself, together with a selection of
interfaces for connecting the core the the user FPGA logic. The board-specific module instantiates
all the FPGA- and system-specific parts (related to WR), such as hard IP provided by the FPGA
vendor, interfaces to DACs, reset inputs, etc.

The BSPs make use internally of the appropriate FPGA family platform support packages (PSPs, see also
Section~\ref{sec:hdl_platform}). For users who need more control and flexibility over their designs,
it is suggested to use the BSP as a reference, and to consider instantiating directly the respective
PSP for their FPGA family.

\subsubsection{Common}
\label{sec:hdl_board_common}

Most of the generic parameters and ports of the board-common module map directly to those of the
WRPC. One notable exception to this rule is that of the parameters and ports related to the selected
interface for connecting the core to the user FPGA logic.

The board-common module provides the \tts{g\_fabric\_iface} generic parameter, an enumeration
type with three possible values:

\begin{description}
\item[PLAIN:] No additional module is instantiated and the ``raw'' WRPC fabric interface (see also
  Section~\ref{sec:wrpc_fabric}) is provided on the board's ports.
\item[STREAMERS:] A set of \href{http://www.ohwr.org/projects/wr-cores/wiki/WR_Streamers}{TX/RX
  streamers} is attached to the WRPC fabric interface.
\item[ETHERBONE:] An \href{http://www.ohwr.org/projects/etherbone-core/wiki}{Etherbone} slave node
  is attached to the WRPC fabric interface.
\end{description}

Sections~\ref{sec:hdl_board_common_param} and~\ref{sec:hdl_board_common_ports} list the generic
parameters and ports of the board-common module which are shared across the BSPs.

\textbf{Note:} the board-common module defines more parameters and ports than the ones mentioned in
the following sections. Those that are not exposed by any of the BSPs have been left out to keep the
tables short and to the point. Users interested in studying the board-common module and/or writing
their own BSP, can find the board-common module under:
\\\hrefwrpc{board/common/xwrc\_board\_common.vhd}

\newpage
\newparagraph{Generic parameters}
\label{sec:hdl_board_common_param}

\begin{hdlparamtable}
  g\_simulation & integer & 0 & \multirowpar{11}{These map directly to generic parameters with the
    same name in the WRPC module (see Section~\ref{sec:wrc_generics})}\\
  \cline{1-3}
  g\_with\_external\_clock\_input & boolean & true & \\
  \cline{1-3}
  g\_board\_name & string & "NA   " & \\
  \cline{1-3}
  g\_flash\_secsz\_kb & integer & 256 & \\
  \cline{1-3}
  g\_flash\_sdbfs\_baddr & integer & 0x600000 & \\
  \cline{1-3}
  g\_aux\_clks & integer & 0 & \\
  \cline{1-3}
  g\_dpram\_initf & string & "" & \\
  \cline{1-3}
  g\_diag\_id & integer & 0 & \\
  \cline{1-3}
  g\_diag\_ver & integer & 0 & \\
  \cline{1-3}
  g\_diag\_ro\_size & integer & 0 & \\
  \cline{1-3}
  g\_diag\_rw\_size & integer & 0 & \\
  \hline
  g\_streamers\_op\_mode & enum & TX\_AND\_RX & Selects whether both TX and RX
  streamer modules should be instantiated or only one of them when
  \tts{g\_fabric\_iface = STREAMERS} (otherwise ignored)\\
  \hline
  g\_tx\_streamer\_params & record & default record & \multirowpar{2}{various TX/RX
    streamers parameters when \tts{g\_fabric\_iface = STREAMERS} (otherwise
    ignored)\footnote{See Streamers wiki page for detailed description of the
    configuration records:
    \url{http://www.ohwr.org/projects/wr-cores/wiki/TxRx_Streamers}}}\\
  \cline{1-3}
  g\_rx\_streamers\_params & record & default record & \\
  \hline
  g\_fabric\_iface & enum & PLAIN & optional module to be attached to the
  fabric interface of WRPC \tts{[PLAIN/STREAMERS/ETHERBONE]}\\
\end{hdlparamtable}

\newparagraph{Ports}
\label{sec:hdl_board_common_ports}

\begin{hdlporttable}
  \hdltablesection{Clocks and resets}\\
  \hline
  clk\_aux\_i & in & var & [optional] vector of auxiliary
  clocks that will be disciplined to WR timebase. Size is equal to \tts{g\_aux\_clks}\\
  \hline
  clk\_10m\_ext\_i & in & 1 & 10MHz external reference clock input
  (used when \tts{g\_with\_external\_clock\_input = true})\\
  \hline
  pps\_ext\_i & in & 1 & external 1-PPS input (used when
  \tts{g\_with\_external\_clock\_input = true})\\
  \hline
  clk\_sys\_62m5\_o & out & 1 & 62.5MHz system clock output\\
  \hline
  clk\_ref\_125m\_o & out & 1 & 125MHz reference clock output\\
  \hline
  rst\_62m5\_n\_o & out & 1 & Active low reset output, synchronous to \tts{clk\_sys\_62m5\_o}\\
  \hline
  rst\_125m\_n\_o & out & 1 & Active low reset output, synchronous to \tts{clk\_ref\_125m\_o}\\
  \hline
  \hdltablesection{Interface with SFP}\\
  \hline
  sfp\_tx\_fault\_i & in & 1 & TX fault indicator\\
  \hline
  sfp\_los\_i & in & 1 & Loss Of Signal indicator\\
  \hline
  sfp\_tx\_disable\_o & out & 1 & TX disable control\\
  \hline
  \hdltablesection{I2C EEPROM interface}\\
  \hline
  eeprom\_sda\_i & in  & 1 & \multirowpar{2}{EEPROM I2C SDA}\\
  \cline{1-3}
  eeprom\_sda\_o & out & 1 & \\
  \hline
  eeprom\_scl\_i & in  & 1 & \multirowpar{2}{EEPROM I2C SCL}\\
  \cline{1-3}
  eeprom\_scl\_o & out & 1 & \\
  \hline
  \hdltablesection{Onewire interface (UID and temperature)}\\
  \hline
  onewire\_i & in  & 1 & OneWire data input\\
  \hline
  onewire\_oen\_o & out & 1 & OneWire data output enable (when asserted,
  OneWire tri-state output buffer should be enabled and driven to ground)\\
  \hline
  \hdltablesection{External WishBone interface}\\
  \hline
  wb\_slave\_o & out & rec & \multirowpar{2}{Mapped to WRPC external WB slave
    interface (see also Section~\ref{sec:wrpc_wb})}\\
  \cline{1-3}
  wb\_slave\_i & in & rec & \\
  \hline
  aux\_master\_o & out & rec & \multirowpar{2}{Mapped to WRPC auxiliary WB
  master interface (see also Section~\ref{sec:wrpc_wb})}\\
  \cline{1-3}
  aux\_master\_i & in & rec & \\
  \hline
  \hdltablesection{WR fabric interface (when \tts{g\_fabric\_iface = plain})}\\
  \hline
  wrf\_src\_o & out & rec & \multirowpar{4}{Mapped to WRPC fabric interface
    (see also Section~\ref{sec:wrpc_fabric})}\\
  \cline{1-3}
  wrf\_src\_i & in &  rec & \\
  \cline{1-3}
  wrf\_snk\_o & out & rec & \\
  \cline{1-3}
  wrf\_snk\_i & in &  rec & \\
  \hline
  \hdltablesection{WR streamers (when \tts{g\_fabric\_iface = streamers})}\\
  \hline
  wrs\_tx\_data\_i & in &  var & Data to be sent. Size is equal to \tts{g\_tx\_streamer\_width}\\
  \hline
  wrs\_tx\_valid\_i & in & 1 & Indicates whether \tts{wrs\_tx\_data\_i} contains valid data\\
  \hline
  wrs\_tx\_dreq\_o & out & 1 & When active, the user may send a data word in the
  following clock cycle\\
  \hline
  wrs\_tx\_last\_i & in &  1 & Can be used to indicate the last data word in a
  larger block of samples\\
  \hline
  wrs\_tx\_flush\_i & in &  1 & When asserted, the streamer will immediatly send
  out all the data that is stored in its TX buffer\\
  \hline
  wrs\_tx\_cfg\_i & in & rec & \multirowpar{2}{Networking configuration of Tx/Rx
  Streamers\footnote{See Streamers wiki page for detailed description of the
    network configuration:
    \url{http://www.ohwr.org/projects/wr-cores/wiki/TxRx_Streamers}}}\\
  \cline{1-3}
  wrs\_rx\_cfg\_i & in & rec & \\
  \hline
  wrs\_rx\_first\_o & out & 1 & Indicates the first word of the data block on \tts{wrs\_rx\_data\_o}\\
  \hline
  wrs\_rx\_last\_o & out & 1 & Indicates the last word of the data block on \tts{wrs\_rx\_data\_o}\\
  \hline
  wrs\_rx\_data\_o & out & var & Received data. Size is equal to \tts{g\_rx\_streamer\_width}\\
  \hline
  wrs\_rx\_valid\_o & out & 1 & Indicates that \tts{wrs\_rx\_data\_o} contains valid data\\
  \hline
  wrs\_rx\_dreq\_i & in &  1 & When asserted, the streamer may output another data word in the
  subsequent clock cycle\\
  \hline
  \hdltablesection{Etherbone WB master interface (when \tts{g\_fabric\_iface = etherbone})}\\
  \hline
  \linebreak wb\_eth\_master\_o\linebreak & out & rec & \multirowpar{2}{WB master interface for the
    Etherbone core. Normally this is attached to a slave port of the primary WB crossbar in the design,
    in order to provide access to all WB peripherals over Etherbone}\\
  \cline{1-3}
  \linebreak wb\_eth\_master\_i\linebreak & in & rec & \\
  \hline
  \hdltablesection{Generic diagnostics interface}\\
  \hline
  \linebreak aux\_diag\_i\linebreak & in & var & \multirowpar{2}{Arrays of 32~bit vectors, to be
    accessed from WRPC via SNMP or uart console. Input array contains \tts{g\_diag\_ro\_size},
    while output array contains \tts{g\_diag\_rw\_size} elements.}\\
  \cline{1-3}
  \linebreak aux\_diag\_o\linebreak & out & var & \\
  \hline
  \hdltablesection{Auxiliary clocks control}\\
  \hline
  tm\_dac\_value\_o & out & 24 & DAC value for tuning auxiliary clock
  (\emph{clk\_aux\_i})\\
  \hline
  tm\_dac\_wr\_o & out & var & validates auxiliary DAC value. Size is equal
  to \tts{g\_aux\_clks}\\
  \hline
  tm\_clk\_aux\_lock\_en\_i & in & var & enable locking auxiliary clock to
  internal WR clock. Size is equal to \tts{g\_aux\_clks}\\
  \hline
  tm\_clk\_aux\_locked\_o & out & var & auxiliary clock locked to internal WR
  clock. Size is equal to \tts{g\_aux\_clks}\\
  \hline \pagebreak 
  \hdltablesection{External TX timestamp interface}\\
  \hline
  timestamps\_o & out & rec & Record-based output ports for
  the TX timestamp interface (see also Section~\ref{sec:txts})\\
  \hline
  txtsu\_ack\_i & in & 1 & acknowledge, indicating that user-defined module
  has received the timestamp\\
  \hline 
  abscal\_txts\_o & out & 1 & \multirowpar{2}{[optional] Endpoint timestamping
  triggers used in the absolute calibration procedure} \\
  \cline{1-3}
  abscal\_rxts\_o & out & 1 & \\
  \hline
  \hdltablesection{Pause frame control}\\
  \hline
  fc\_tx\_pause\_req\_i   & in  &  1 & [optional] Ethernet flow control, request sending
  Pause frame\\
  \hline
  fc\_tx\_pause\_delay\_i & in  & 16 & [optional] Pause quanta\\
  \hline
  fc\_tx\_pause\_ready\_o & out &  1 & [optional] Pause acknowledge - active after the
  current pause send request has been completed\\
  \hline
  \hdltablesection{WRPC timecode interface}\\
  \hline
  tm\_link\_up\_o & out & 1 & state of Ethernet link (up/down), \emph{1}
  means Ethernet link is up\\
  \hline
  tm\_time\_valid\_o & out & 1 & if \emph{1}, the timecode generated by the
  WRPC is valid\\
  \hline
  tm\_tai\_o & out & 40 & TAI part of the timecode (full seconds)\\
  \hline
  tm\_cycles\_o & out & 28 & fractional part of each second represented by
  the state of counter clocked with the frequency 125 MHz (values from 0 to
  124999999, each count is 8 ns)\\
  \hline
  \hdltablesection{Buttons, LEDs and PPS output}\\
  \hline
  led\_act\_o & out & 1 & signal for driving Ethernet activity LED\\
  \hline
  led\_link\_o & out & 1 & signal for driving Ethernet link LED\\
  \hline
  btn1\_i & in & 1 & \multirowpar{2}{two microswitch inputs, active low, currently not
    used in official WRPC software}\\
  \cline{1-3}
  btn2\_i & in & 1 & \\
  \hline
  pps\_p\_o & out & 1 & 1-PPS signal generated in \tts{clk\_ref\_i} clock
  domain and aligned to WR time, pulse generated when the cycle counter is 0
  (beginning of each full TAI second)\\
  \hline
  pps\_led\_o & out & 1 & 1-PPS signal with extended pulse width to drive a LED\\
  \hline
  link\_ok\_o & out & 1 & Link status indicator\\
\end{hdlporttable}

\subsubsection{SPEC}
\label{sec:hdl_board_spec}

The SPEC BSP provides a ready-to-use WRPC wrapper for the
\href{http://www.ohwr.org/projects/spec}{SPEC carrier board}.

The top-level VHDL module is located under: \\\hrefwrpc{board/spec/xwrc\_board\_spec.vhd}

An alternative top-level VHDL module which only makes use of standard logic for ports and integers
and strings for generic parameters (ideal for instantiation in Verilog-based designs) can be found
under: \\\hrefwrpc{board/spec/wrc\_board\_spec.vhd}

A VHDL package with the definition of both modules can be found under:
\\\hrefwrpc{board/spec/wr\_spec\_pkg.vhd}

An example (VHDL) instantiation of this module can be found in the SPEC WRPC reference design:
\\\hrefwrpc{top/spec\_ref\_design/spec\_wr\_ref\_top.vhd}

This section describes the generic parameters and ports which are specific to the SPEC BSP.
Parameters and ports common to all BSPs are described in Section~\ref{sec:hdl_board_common}.

\newparagraph{Generic parameters}

No additional generic parameters are declared in the SPEC BSP. See
Section~\ref{sec:hdl_board_common_param} for a the list of common BSP parameters.


\newparagraph{Ports}

\begin{hdlporttable}
  \hdltablesection{Clocks and resets}\\
  \hline
  areset\_n\_i & in & 1 & Reset input (active low, can be async)\\
  \hline
  areset\_edge\_n\_i & in & 1 & [optional] Reset input edge sensitive (active
  rising-edge, can be async). Should be connected to PCIe reset if the board
  should be able to operate both in hosted and standalone configuration.\\
  \hline
  clk\_20m\_vcxo\_i & in & 1 & 20MHz clock input from board VCXO\\
  \hline
  clk\_125m\_pllref\_p\_i & in & 1 & \multirowpar{2}{125MHz PLL reference
    differential clock input from board}\\
  \cline{1-3}
  clk\_125m\_pllref\_n\_i & in & 1 & \\
  \hline
  clk\_125m\_gtp\_p\_i & in & 1 & \multirowpar{2}{125MHz GTP
    reference differential clock input from board}\\
  \cline{1-3}
  clk\_125m\_gtp\_n\_i & in & 1 & \\
  \hline
  \hdltablesection{SPI interface to DACs}\\
  \hline
  plldac\_sclk\_o & out & 1 & SPI SCLK, common to both DACs\\
  \hline
  plldac\_din\_o & out & 1 & SPI MOSI, common to both DACs\\
  \hline
  pll25dac\_cs\_n\_o & out & 1 & SPI $\overline{\mbox{SS}}$ for DAC controlling 25MHz oscillator\\
  \hline
  pll20dac\_cs\_n\_o & out & 1 & SPI $\overline{\mbox{SS}}$ for DAC controlling 20MHz oscillator\\
  \hline
  \hdltablesection{SFP interface}\\
  \hline
  sfp\_txn\_o & out & 1 & \multirowpar{2}{differential pair for PHY TX}\\
  \cline{1-3}
  sfp\_txp\_o & out & 1 & \\
  \hline
  sfp\_rxn\_i & in & 1 & \multirowpar{2}{differential pair for PHY RX}\\
  \cline{1-3}
  sfp\_rxp\_i & in & 1 & \\
  \hline
  sfp\_det\_i & in  & 1 & Active low, indicates presence of SFP (corresponds to SFP MOD-DEF0)\\
  \hline
  sfp\_sda\_i & in  & 1 & \multirowpar{2}{SFP I2C SDA}\\
  \cline{1-3}
  sfp\_sda\_o & out & 1 & \\
  \hline
  sfp\_scl\_i & in  & 1 & \multirowpar{2}{SFP I2C SCL}\\
  \cline{1-3}
  sfp\_scl\_o & out & 1 & \\
  \hline
  sfp\_rate\_select\_o & out & 1 & SFP rate select\\
  \hline
  \hdltablesection{Physical UART interface}\\
  \hline
  uart\_rxd\_i & in  & 1 & UART RXD (serial data to WRPC)\\
  \hline
  uart\_txd\_o & out & 1 & UART TXD (serial data from WRPC)\\
  \hline
  \hdltablesection{Flash memory SPI interface}\\
  \hline
  flash\_sclk\_o & out & 1 & Flash SPI SCLK\\
  \hline
  flash\_ncs\_o  & out & 1 & Flash SPI $\overline{\mbox{SS}}$\\
  \hline
  flash\_mosi\_o & out & 1 & Flash SPI MOSI\\
  \hline
  flash\_miso\_i & in  & 1 & Flash SPI MISO\\
\end{hdlporttable}

\subsubsection{SVEC}
\label{sec:hdl_board_svec}

The SVEC BSP provides a ready-to-use WRPC wrapper for the
\href{http://www.ohwr.org/projects/svec}{SVEC carrier board}.

The top-level VHDL module is located under: \\\hrefwrpc{board/svec/xwrc\_board\_svec.vhd}

An alternative top-level VHDL module which only makes use of standard logic for ports and integers
and strings for generic parameters (ideal for instantiation in Verilog-based designs) can be found
under: \\\hrefwrpc{board/svec/wrc\_board\_svec.vhd}

A VHDL package with the definition of both modules can be found under:
\\\hrefwrpc{board/svec/wr\_svec\_pkg.vhd}

An example (VHDL) instantiation of this module can be found in the SVEC WRPC reference design:
\\\hrefwrpc{top/svec\_ref\_design/svec\_wr\_ref\_top.vhd}

This section describes the generic parameters and ports which are specific to the SVEC BSP.
Parameters and ports common to all BSPs are described in Section~\ref{sec:hdl_board_common}.

\newparagraph{Generic parameters}

No additional generic parameters are declared in the SVEC BSP. See
Section~\ref{sec:hdl_board_common_param} for a the list of common BSP parameters.

\newparagraph{Ports}

\begin{hdlporttable}
  \hdltablesection{Clocks and resets}\\
  \hline
  areset\_n\_i & in & 1 & Reset input (active low, can be async)\\
  \hline
  areset\_edge\_n\_i & in & 1 & [optional] Reset input edge sensitive (active
  rising-edge, can be async).\\
  \hline
  clk\_20m\_vcxo\_i & in & 1 & 20MHz clock input from board VCXO\\
  \hline
  clk\_125m\_pllref\_p\_i & in & 1 & \multirowpar{2}{125MHz PLL reference
    differential clock input from board}\\
  \cline{1-3}
  clk\_125m\_pllref\_n\_i & in & 1 & \\
  \hline
  clk\_125m\_gtp\_p\_i & in & 1 & \multirowpar{2}{125MHz GTP
    reference differential clock input from board}\\
  \cline{1-3}
  clk\_125m\_gtp\_n\_i & in & 1 & \\
  \hline
  \hdltablesection{SPI interface to DACs}\\
  \hline
  pll20dac\_sclk\_o & out & 1 & SPI SCLKfor DAC controlling 20MHz oscillator\\
  \hline
  pll20dac\_din\_o & out & 1 & SPI MOSI for DAC controlling 20MHz oscillator\\
  \hline
  pll20dac\_cs\_n\_o & out & 1 & SPI $\overline{\mbox{SS}}$ for DAC controlling 20MHz oscillator\\
  \hline
  pll25dac\_sclk\_o & out & 1 & SPI SCLK for DAC controlling 25MHz oscillator\\
  \hline
  pll25dac\_din\_o & out & 1 & SPI MOSI for DAC controlling 25MHz oscillator\\
  \hline
  pll25dac\_cs\_n\_o & out & 1 & SPI $\overline{\mbox{SS}}$ for DAC controlling 25MHz oscillator\\
  \hline
  \hdltablesection{SFP interface}\\
  \hline
  sfp\_txn\_o & out & 1 & \multirowpar{2}{differential pair for PHY TX}\\
  \cline{1-3}
  sfp\_txp\_o & out & 1 & \\
  \hline
  sfp\_rxn\_i & in & 1 & \multirowpar{2}{differential pair for PHY RX}\\
  \cline{1-3}
  sfp\_rxp\_i & in & 1 & \\
  \hline
  sfp\_det\_i & in  & 1 & Active low, indicates presence of SFP (corresponds to SFP MOD-DEF0)\\
  \hline
  sfp\_sda\_i & in  & 1 & \multirowpar{2}{SFP I2C SDA}\\
  \cline{1-3}
  sfp\_sda\_o & out & 1 & \\
  \hline
  sfp\_scl\_i & in  & 1 & \multirowpar{2}{SFP I2C SCL}\\
  \cline{1-3}
  sfp\_scl\_o & out & 1 & \\
  \hline
  sfp\_rate\_select\_o & out & 1 & SFP rate select\\
  \hline
  \hdltablesection{Physical UART interface}\\
  \hline
  uart\_rxd\_i & in  & 1 & UART RXD (serial data to WRPC)\\
  \hline
  uart\_txd\_o & out & 1 & UART TXD (serial data from WRPC)\\
  \hline
  \hdltablesection{Flash memory SPI interface}\\
  \hline
  spi\_sclk\_o & out & 1 & Flash SPI SCLK\\
  \hline
  spi\_ncs\_o  & out & 1 & Flash SPI $\overline{\mbox{SS}}$\\
  \hline
  spi\_mosi\_o & out & 1 & Flash SPI MOSI\\
  \hline
  spi\_miso\_i & in  & 1 & Flash SPI MISO\\
\end{hdlporttable}

\subsubsection{VFC-HD}
\label{sec:hdl_board_vfchd}

The VFC-HD BSP provides a ready-to-use WRPC wrapper for the
\href{http://www.ohwr.org/projects/vfc-hd}{VFC-HD carrier board}.

The top-level VHDL module is located under: \\\hrefwrpc{board/vfchd/xwrc\_board\_vfchd.vhd}

An alternative top-level VHDL module which only makes use of standard logic for ports and integers
and strings for generic parameters (ideal for instantiation in Verilog-based designs) can be found
under: \\\hrefwrpc{board/vfchd/wrc\_board\_vfchd.vhd}

A VHDL package with the definition of both modules can be found under:
\\\hrefwrpc{board/vfchd/wr\_vfchd\_pkg.vhd}

An example (VHDL) instantiation of this module can be found in the VFC-HD WRPC reference design:
\\\hrefwrpc{top/vfchd\_ref\_design/vfchd\_wr\_ref\_top.vhd}

This section describes the generic parameters and ports which are specific to the VFC-HD BSP.
Parameters and ports common to all BSPs are described in Section~\ref{sec:hdl_board_common}.

\newparagraph{Generic parameters}

\begin{hdlparamtable}
  g\_pcs16\_bit & boolean & false & Altera Arria V FPGAs provide the possibility
  to configure the PCS of the PHY as either 8bit or 16bit. The default is to use
  the 8bit PCS. Currently, 16bit PCS is not supported for Arria V.\\
\end{hdlparamtable}

\newparagraph{Ports}

\begin{hdlporttable}
  \hdltablesection{Clocks and resets}\\
  \hline
  areset\_n\_i & in & 1 & Reset input (active low, can be async)\\
  \hline
  areset\_edge\_n\_i & in & 1 & [optional] Reset input edge sensitive (active
  rising-edge, can be async).\\
  \hline
  clk\_board\_20m\_i & in & 1 & 20MHz clock input from board\\
  \hline
  clk\_board\_125m\_i & in & 1 & 125MHz reference clock input from board\\
  \hline
  \hdltablesection{SPI interface to DACs}\\
  \hline
  dac\_sclk\_o & out & 1 & SPI SCLK, common to both DACs\\
  \hline
  dac\_din\_o & out & 1 & SPI MOSI, common to both DACs\\
  \hline
  dac\_ref\_sync\_n\_o & out & 1 & SPI $\overline{\mbox{SS}}$ for DAC controlling 125MHz oscillator\\
  \hline
  dac\_dmtd\_sync\_n\_o & out & 1 & SPI $\overline{\mbox{SS}}$ for DAC controlling 20MHz oscillator\\
  \hline
  \hdltablesection{SFP interface}\\
  \hline
  sfp\_tx\_o & out & 1 & PHY TX\\
  \hline
  sfp\_rx\_i & in & 1 & PHY RX\\
  \hline
  sfp\_det\_i & in  & 1 & Active high, asserted if all of the following are true:\linebreak
  * SFP is detected (plugged in)\linebreak
  * The part number has been successfully read\\
  \hline
  sfp\_data\_i & in  & 128 & 16 byte SFP vendor Part Number (ASCII encoded, first character byte
  in bits 127 downto 120)\\

\end{hdlporttable}
